Hemofiltration system

ABSTRACT

A hemofiltration system and method is provided that allows for high flow rate, accurate determination of net fluid withdrawal from or addition to a patient, and simple and reliable home operation. A removable, disposable assembly includes a filter housing and pump member including one or more fluid conduits mounted against the pump member. When the disposable filter/pump member assembly is attached to the treatment system, a pump roller mechanism associated with the system actuates the conduits mounted against the pump member. A disposable waste receptacle and fluid replacement (infusate) reservoir can be provided as an integral part of the disposable filter/pump member assembly.

FIELD OF THE INVENTION

[0001] The present invention relates generally to man-made apparatusthat substitutes for natural kidney function, and more particularly to acompact, easy-to-use hemofiltration system equipped to maintain accuratenet fluid volume change in a patient, and designed and constructed to beusable repeatable in a patient's home.

BACKGROUND OF THE INVENTION

[0002] Loss of human renal function, for example due to kidney disease,affects hundreds of thousands of people worldwide. In the past, chronicrenal failure has meant almost certain death. More recently, renalfailure is treatable by kidney transplant and/or less-physiologicallytraumatic procedures such as hemodialysis or hemofiltration. Existinghemodialysis and hemofiltration systems operate by continuouslywithdrawing blood from a patient, treating the blood to remove waste,and continuously re-introducing treated blood into the patient.Hemodialysis operates by bringing blood into contact with one side of asemi-permeable membrane while a dialysis solution (dialysate) is broughtinto contact with the other side of the membrane. Uremic toxins diffuseout of the blood, through the semi-permeable membrane due toconcentration gradient across the membrane, and into the dialysate.Hemofiltration operates by passing the blood through a filter to removewaste.

[0003] Most man-made renal function systems are not designed forconvenient home use. In general, artificial renal treatment is given ina clinical outpatient setting for reasons of safety, since factors suchas balance in withdrawn blood and re-introduced replacement fluids arecritical. Of course, loss of a threshold amount of blood results indeath. However, since victims of renal failure treated by man-made renalfunction systems must spend a significant amount of time undergoinghemofiltration or hemodialysis, these patients must spend a significantamount of time out of their homes if treated in a clinical setting.

[0004] Accordingly, there is a need in the art for high-volume,convenient, and accurate hemofiltration systems that allow for safe andeasy home use.

SUMMARY OF THE INVENTION

[0005] The present invention provides a set of techniques and systemsfor providing treatment to patients in need of renal therapy. In oneaspect, the invention involves a method of clearing a patient's blood ofuremic toxins. The method involves subjecting a patient in need of renaltherapy to a protocol involving continuously removing blood from apatient at a blood flow rate of at least 300 ml/min, at least partiallyclearing the blood of uremic toxins to create cleared blood, andcontinuously returning the cleared blood to the patient. The protocol isrepeated at least four times in one week. The protocol can be repeatedfive times, six times, or seven times in one week according to variousembodiments, and any of these embodiments can be repeated for two weeks,three weeks, one month, two months, or an extended period of time.Typically, these treatments will be repeated 4-7 times per week for manyyears. The method can be facilitated by one aspect of the invention inwhich the protocol involves renal therapy at a blood flow rate of atleast 400 ml/min. The flow rate can be 500 ml/min, 600 ml/min, or 700ml/min according to another set of embodiments, and any member of thisset of embodiments can be combined with any of the above and otherembodiments. For example, the method can involve subjecting a patient inneed of renal therapy to blood treatment at a flow rate of at least 300ml/min at least four times per week, or, for example, at least 600ml/min at least six times per week. The method can involve accessing apatient's vascular systems through a subcutaneous port, removing theblood from the patient, at least partially clearing the blood, andreturning cleared blood to the patient, optionally via the same or adifferent subcutaneous port.

[0006] The methods and systems of the invention facilitate very highclearance rate treatment. One embodiment involves clearing a patient'sblood of uremic toxins via hemofiltration at an effective clearance rateof at least 100 ml/min, preferably at least 200 ml/min.

[0007] The systems and methods of the invention allow for maintenance ofa uremic toxin level in a patient within a convenience and comfortrange. That is, because the invention provides a system for convenientin-home hemofiltration therapy, a protocol is facilitated in which apatient's uremic toxins are allowed to reach no more than about 80% ofthe maximum level compared to thrice-weekly therapy levels, followingwhich the patient's blood is treated to reduce toxins and treatmentcontinues only so long as the blood toxin level is at least 20% of themaximum level compared to thrice-weekly therapy levels. The protocol isrepeated at least four times in one week.

[0008] The invention also provides a self-contained system for clearinga patient's blood of uremic toxins. The system includes a filter havinga first side fluidly connectable to a source of a patient's blood and asecond side fluidly connectable to a waste receptacle. A reservoir isprovided that contains from about four to about 25 liters of infusate,and the reservoir is fluidly connectable to the patient's blood stream.The infusate reservoir can contain from about 4 to about 18 liters, orfrom about 9 to about 13, or 10 to about 12 liters in preferred, singleday embodiments.

[0009] In another embodiment, the invention provides a system forclearing a patient's blood of uremic toxins, including a filter having afirst side and a second side, an input conduit in fluid communicationwith the first side of the filter and fluidly connectable to a patient'sblood stream, a return conduit in fluid communication with the firstside of the filter for returning cleared blood to the patient's bloodstream, a waste receptacle, a waste conduit fluidly connecting the wastereceptacle to the second side of the filter, a reservoir containing fromabout 4 to about 25 liters of infusate, and an infusate conduit fluidlyconnecting the reservoir to the return conduit. The invention alsoprovides a system including a peristaltic pump, and a fluid conduitpassing through the pump and having a portion upstream of the pump. Thesystem includes a valve in the portion of the fluid conduit upstream ofthe pump.

[0010] Also provided in accordance with the invention is a methodincluding adjusting the rate of fluid flow through a peristaltic pump byadjusting the resistance to fluid flow upstream of the pump.

[0011] The invention also provides a method including establishing aflow of fluid through a peristaltic pump from a source of the fluid, andchanging the rate of flow of the fluid through the peristaltic pumpwhile the pump operates at a constant speed and the source of fluidremains constant. The invention also provides a method includingcontrolling an amount of a replacement fluid added from a reservoir to ablood stream of a patient in response to a signal generated fromcomparison of (a) a total amount of unaccumulated waste product removedfrom the blood stream and the replacement fluid in the reservoir with(b) one of the amount of the accumulated waste product and thereplacement fluid in the reservoir.

[0012] The invention also provides a system including a blood treatmentdevice having an input fluidly connectable to a source of blood drawnfrom a patient in need of renal treatment, and an output fluidlyconnectable to a receptacle of blood waste product. The system includesa first scale adapted to determine a first value that is a total amountof the content of the receptacle of blood waste product plus an amountof blood replacement fluid (infusate) in a reservoir. A second scale isprovided that is adapted to determine a second value that is at leastone of the content of the receptacle of blood waste product or theamount of blood replacement fluid in the reservoir. A microprocessor isprovided that is capable of generating a signal indicative of acomparison of the first value and the second value, and a controller isincluded that is capable of controlling delivery of blood replacementfluid to the patient's blood stream in response to the signal.

[0013] The invention also provides a method including urgingsimultaneously the flow of first and second physiological fluids withinfirst and second conduits, respectively, via actuation of a single fluidpump actuator. The fluid pump can be a peristaltic pump.

[0014] The invention also provides a fluid pump. The pump is constructedand arranged for use with a blood treatment system. The treatment systemincludes a blood treatment device, a withdrawal conduit arranged tosupply a source of blood from a patient in need of renal treatment thetreatment device, a return conduit arranged to return treated blood fromthe treatment device to the patient, a waste product conduit arranged todeliver waste product removed from the blood by the treatment device toa waste outlet, and a replacement fluid conduit arranged to deliver areplacement fluid to the patient. The fluid pump is constructed andarranged to urge fluid to flow within at least two of the withdrawalconduit, the return conduit, the waste product conduit, and thereplacement fluid conduit. Preferably, the fluid pump is constructed andarranged to urge fluid to flow through the withdrawal conduit, the wasteproduct conduit, and the infusate (replacement fluid) conduit.

[0015] The invention also provides an assembly for use with a bloodtreatment system. The assembly is removably attachable to the system,and includes a blood filter housing having an inlet, a first outlet, anda second outlet. The assembly includes a pump member having a surfacethat mates with a pump in the treatment system when the assembly isattached to the treatment system. A withdrawal conduit is provided thatis in fluid communication with the filter housing inlet and fluidlyconnectable to a source of blood from a patient in need of renaltreatment. A return conduit is provided in fluid communication with thefirst filter housing outlet and is fluidly connectable to a conduit forreturning the treated blood to the patient. A waste product conduit isprovided in fluid communication with the second filter housing outlet.At least two of the withdrawal conduit, the return conduit, and thewaste product conduit are arranged proximate the pump member surfacesuch that, when the assembly is attached to the treatment system, the atleast two conduits are actuable by the pump.

[0016] The invention also provides a system including a conduit fluidlyconnectable to a patient's vascular system, and an ultrasonic sensorresponsive to fluid flow in the conduit. The sensor includes an outputfor delivering a signal indicative of fluid flow rate in conduit. Analarm can be provided, responsive to the signal, that is activated whenfluid flow strays outside a predetermined range, and in particular whenthe fluid flow drops between a predetermined level.

[0017] The invention also provides a system for clearing a patient'sblood of uremic toxins. The system includes a subcutaneous portproviding fluid communication with a patient's vascular system, a filterhaving a first side and a second side, an input conduit in fluidcommunication with the first side of the filter and fluidly connectableto the subcutaneous port, a return conduit in fluid communication withthe first side of the filter for returning cleared blood to thepatient's blood stream, a waste receptacle, a waste conduit fluidlyconnecting the waste receptacle to the second side of the filter, areservoir containing from about 4 to about 25 liters of infusate, and aninfusate conduit fluidly connecting the reservoir to the return conduit.The system is constructed and arranged to continuously clear the bloodof uremic toxins to create cleared blood at a blood flow rate of atleast 300 ml/min.

[0018] Other advantages, novel features, and objects of the inventionwill become apparent from the following detailed description of theinvention when considered in conjunction with the accompanying drawings,which are schematic and which are not intended to be drawn to scale. Inthe figures, each identical or nearly identical component that isillustrated in various figures is represented by a single numeral. Forpurposes of clarity, not every component is labeled in every figure.

BRIEF DESCRIPTION OF THE DRAWINGS

[0019]FIG. 1 is an estimated plot of effective blood clearance(treatment rate) versus blood flow rate for hemodialysis (curve A) andhemofiltration (curve B) systems;

[0020]FIG. 2 is a suggested plot of blood toxin level versus days in abi-daily hemodialysis protocol (curve C) and a daily hemofiltrationprotocol (curve D);

[0021]FIG. 3 is a schematic illustration of a high flow rate,subcutaneous vascular access port;

[0022]FIG. 4 is a schematic illustration of a hemofiltration system ofthe invention;

[0023]FIG. 5 is a schematic illustration of a pump arrangement of theinvention;

[0024]FIG. 6 is a partial cross-sectional view through lines 3-3 of FIG.2;

[0025]FIG. 7 is a schematic illustration of a pump race, filter housing,replacement fluid reservoir, and waste receptacle in accordance with theinvention including a device for sensing the flow of replacement fluidfrom the reservoir;

[0026]FIG. 8 is a schematic illustration of a blood treatment system ofthe invention; and

[0027]FIG. 9 is a schematic illustration of a blood treatment systemaccording to another embodiment of the invention.

DETAILED DESCRIPTION OF THE INVENTION

[0028] The present invention provides a system for the treatment ofblood in patients requiring renal therapy, for example in patientssuffering renal failure. The system is constructed to be simple tooperate safely in the home and allows for the possibility of safe andconvenient daily hemofiltration treatments. The hemofiltration therapyfacilitated by the system involves passing blood drawn from a patientthrough a filter to remove uremic toxins (waste material that is removedphysiologically by a healthy kidney), and subsequent re-infusion of theblood into the patient. An infusate, or replacement fluid, is added tothe blood returned to the patient to at least in part make up for theamount of fluid removed during the filtration process. Typically, fluidwill be replaced in an amount slightly less than that removed todecrease the overall fluid level in the patient.

[0029] A discussion of the state of the art of hemodialysis andhemofiltration systems and of certain factors and parameters recognizedby the inventors of the present invention, will facilitate a betterunderstanding of the implications of the invention. Hemodialysisinvolves establishment of a flow of a patient's blood along a first sideof a semi-permeable membrane in a first direction, and establishment ofa dialysate solution flowing typically in the opposite direction on theopposite side of the membrane. The dialysate has a low concentration(typically zero, initially) of toxins desirably removed from blood, anda concentration gradient of toxin is established across thesemi-permeable membrane causing toxins to diffuse across the membraneout of the blood. The process is limited, ultimately, by the rate ofdiffusion of toxins across the semi-permeable membrane, so maintaining avery low concentration of toxins on the dialysate side of the membraneis the most effective means of increasing the blood treatment rate. Todo this, however, requires large quantities of dialysate, typicallyprovided conveniently only in a clinical setting. Current clinicalhemodialysis protocols require approximately 60-120 liters of dialysateper treatment, an amount not conveniently delivered to the home, andperhaps not safely and conveniently prepared by most potential users inthe home. While U.S. Pat. No. 5,484,397 (Twardowski) describes ahemodialysis system for home use, the system requires synthesis, in thehome, of dialysis solution from dry chemicals, concentrates, and a largevolume of relatively pure water (that is purified in the home).

[0030] Since concentration-gradient-driven diffusion of toxins across amembrane is the primary rate limiting factor in dialysis, treatment ratedoes not increase significantly as blood flow rate adjacent the membraneincreases above a certain point. As illustrated in curve A of FIG. 1(representative of hemodialysis), with increasing blood flow rateadjacent a membrane in a dialysis process, treatment rate increasesharply just above zero flow, but quickly tapers off, that is,diminishes in rate of increase until it reaches an approximate plateauin which any increase in blood flow rate results in very littleresultant increase in blood treatment rate.

[0031] In hemofiltration, on the other hand, achievement of acceptablyhigh treatment rates has been determined to be dependent upon blood flowrate. Hemofiltration involves convection of toxins across a membrane,specifically, passage of blood through an ultrafiltration membrane thatpasses toxins but that restricts the passage of blood cells and othercomponents desirably returned to the patient. The toxins are routed to awaste receptacle, and the blood cells and other components trapped bythe filter are returned to the patient's blood stream. Unlike inhemodialysis, in hemofiltration the rate of blood treatment isindependent of any concentration gradient across the filter, and insteadis dependent upon the rate of clearance of the filter, that is, the rateat which blood cells and other filtrate can be removed from the filterand re-introduced into the patient's bloodstream. The clearance rate is,in turn, dependent only upon the flow rate of the patient's bloodthrough the filter. Therefore, as indicated by curve B of FIG. 1(representative of hemofiltration), as blood flow rate increases inhemofiltration, blood treatment rate increases significantly, especiallyat particularly high blood flow rates. Moreover, the 60-120 liters ofauxiliary fluid, required in hemodialysis (the dialysate), is notrequired in hemofiltration. A flow rate of 400 ml/min is suggested asthat at which hemodialysis, with state of the art membrane surfaceareas, and hemofiltration exhibit similar blood treatment rates(effective clearance rate) at similar blood flow rate. FIG. 1 isrepresentative of generalized trends, and is not intended to be precise.

[0032] Repeatable, high blood flow rates are not, however, readilyachievable. A percutaneous blood flow rate of 420 typically isachievable with a 15 gauge needle through a graft (a subcutaneouspolytetrafluoroethylene tube connecting an artery and a vein and servingas a location for access to the vascular system), and a flow rate of 500can be achieved with a 14 gauge needle through a graft. Access to apatient's vascular system in this manner typically cannot be repeatedindefinitely with regularity. Repeated access to a patient's vascularsystem via a 15 or 14 gauge needle is problematic, and can seriouslyimpact the life of a graft. Needles of this type can “core” grafts, thatis, can cut out a portion of a graft.

[0033] Since hemodialysis typically is carried out in a clinicalsetting, most patients select a treatment protocol that does not requiredaily visits, but only requires treatment every other day. However, asthe frequency of treatment drops, the effectiveness of each treatmentmust be greater. FIG. 2, curve C, is a representative plot of a bi-dailypatient treatment protocol. FIG. 2 does not represent actualexperiments. On day zero, a patient has just undergone renal therapy,and the patient's blood is clear of uremic toxins. Gradually, over thecourse of the next two days, the level of uremic toxins in the bloodincreases until treatment at day two. At day two, just prior totreatment, the level of uremic toxins in the patient's blood has reachedmaximum tolerable level, that is, the maximum level tolerable withoutextreme discomfort. This level of toxin is generally unhealthy. For thepatient to be able to be free of treatment for the next two days, hisblood must be cleared of toxins to the greatest extent feasible, andthat level is represented by toxin level 0 in FIG. 2. Hemodialysisrelatively rapidly can bring the patient's toxin level from 100% down to80% and even 20%, but because hemodialysis (unlike hemofiltration)relies for effectiveness on toxin concentration gradient across amembrane, as blood toxin level decreases, toxin removal slowsconsiderably. The final portion of treatment, in which toxin level isdecreased from 20% to 0, requires a significant amount of time. Yet thattime must be spent unless the patient is willing to return to the clinicfor treatment every day, which most patients, given the choice, will notdo. In summary, hemodialysis in the outpatient clinic setting typicallyinvolves treatment every other day, with some discomfort experienced inthe hours just before treatment because of relatively high toxin levels,and significant treatment time is required to achieve the very low toxinlevels required to avoid the requirement of treatment every day.

[0034] Thus, the invention involves identification of hemofiltration asa much more advantageous treatment technique than hemodialysis, assuminggreater accessible blood flow rate. Hemofiltration would be especiallyeffective for home therapy (if the technique could be made feasible foruse in the home) since the only auxiliary fluid required inhemofiltration is the infusate. Infusate is added only to partiallyreplace waste removed from blood, and is required only in an amount ofabout 8-10 liters per treatment. Treatment in the home would result in atreatment protocol that, for most patients, would be tolerable on adaily basis. If a treatment protocol could be carried out on a dailybasis, then a blood toxin situation such as curve D would result. Incurve D toxin level is maintained at a level no greater than 80% maximumtolerable level, and need not be driven below level 20%. The patient'sblood toxin level increases only to a moderate level (80%) after oneday, and treatment need be carried out only to the extent necessary todrive the toxin level to the 20% level, since over the next day thetoxin level will rise only to 80%. This is advantageous since extra timeand effort required for blood clearance to level 0 is not necessary, andthe patient need not experience discomfort associated with toxin levelsabove 80%. In short, since treatment can be carried out conveniently inthe home (since 60-120 liters of dialysate is not required), the patientis typically willing to experience treatment every day, and as a result,in combination with high flow rates provided by the invention, therequisite treatment times are quite short, making daily treatment evenmore tolerable. Although the data plotted in FIG. 2 is not based onactual experiments, the curves of FIG. 2 are representative in thatbi-daily hemodialysis or hemofiltration typically requires treatmenttimes of about 4 hours, and daily hemofiltration treatments (provided inaccordance with the invention, described in greater detail below)require only about 1.5 hours. Of course, hemodialysis that is carriedout in a clinic also requires travel time, set-up, take-down, and othermiscellaneous activities that can bring the total time to six hours.Thus not only is treatment carried out safely and conveniently in thecomfort of home, according to the in-home daily hemofiltration techniqueof the invention, but time is saved overall.

[0035] The present invention solves, according to one aspect, theproblem associated with high treatment rates for hemofiltration, namelylow blood flow rate, by providing a high-flow-rate access port. The portmakes feasible hemofiltration at rates that reduce treatment times tothose tolerable by patients on a daily basis, and the invention alsoprovides a series of hemofiltration systems for safe, convenient,disposable home use. The high-flow-rate port of the invention allows forsafe, repeatable, reliable access to a patient's vascular system at flowrates of up to 600-700 ml/min. The port is described in detail inco-pending, commonly-owned U.S. patent application of Burbank, et al.,entitled “Valve Port and Method for Vascular Access”, filed Jan. 21,1997 and incorporated herein by reference. High flow rate can befacilitated, also, using a “T” apparatus described in co-pending,commonly-owned, U.S. patent application Ser. No. 08/724,948, filed Nov.20, 1996 by Finch, et al., entitled “Subcutaneously-Implanted Cannulaand Method for Arterial Access”, incorporated herein by reference. Theport (referring to FIG. 3) facilitates high volume withdrawal and/orreturn of blood to a patient undergoing extracorporeal blood therapyincluding hemodialysis, hemofiltration, hemodiafiltration, and the like.The port is implantable subcutaneously and can be accessed by passing aneedle through a patient's skin (percutaneously) and into the port. Portdevice 110 includes an upper shell 118, a base plate 120, an internalcylinder 122, and a vertically reciprocating actuator block 124 disposedwithin the cylinder 122. A spring 126 urges the actuator block 124upwardly relative to the cylinder 122. When the actuator block 124 is inits upward position, a conduit 114 (passing into a vein or artery) ispinched closed between an upper lip 128 which is a portion of the wallof cylinder 122 and a lower lip 130 which is a portion of the actuatorblock 124. Proximal end of the conduit 114 is connected to the lower endof a tube 132 which depends into an interior volume of the actuatorblock 124. The depending tube 132 provides an axial bore 134 forreceiving a needle. A needle is introduced through an opening 136 at theupper end of the axial bore 134.

[0036] A pair of balls 140 are disposed in an upper portion of the tube132 and contained within a circular aperture 142 in the shell 118 on theactuator block 124 as in its raised configuration. When a needle isintroduced through opening 136, it exerts a force on the balls 140thereby depressing the actuator block 124 downward until the blockreaches a lower configuration, causing opposed lips 128 and 132 to openand thereby fluidly connecting conduits 114 and 132. When the needle isinserted, the balls 140 move radially outwardly into an expanded portion144 of the aperture 142, and thus become locked within the expandedregion so long as the needle remains in place.

[0037] The high flow rate access port allows for blood flow rates of atleast 300 ml/min, preferably at least 400 ml/min, more preferably atleast 420 ml/min. Blood flow rates of at least 500 ml/min, at least 600ml/min, and even at least 700 ml/min are achievable with the high flowrate access port. The port can be used in conjunction with othercomponents of the invention to provide an overall arrangement that iseasy to use by most renal failure patients, is reliable, can bemanufactured at relatively low cost, and includes low cost ancillary anddisposable apparatus. The setup of the apparatus is very simple.Integrated, pre-primed disposable components clip into place in anintuitive fashion. In a preferred arrangement, a reusable unit isprovided, and a disposable assembly including a waste receptacle,infusate reservoir, filter, and various conduits is provided that can beconnected to the reusable unit by connection of only two conduitconnectors. The reusable unit is pre-primed such that connection at thetwo connectors, followed by actuation of the reusable unit controlprocessor initiates treatment. The system is constructed such that theunit can be actuated by the user by pressing just one button.

[0038] Assembly and operation of the device is very straightforwardrelative to state-of-the-art units.

[0039] In connection with hemofiltration systems, arrangements are knownfor weighing removed waste and weighing fluid infused to replace removedwaste to maintain a predetermined fluid level in a patient. Systems areknown also for weighing and comparing fresh and spent dialysate inhemodialysis. U.S. Pat. Nos. 4,204,957, 5,344,568, 4,728,433, and4,132,644 can be consulted for discussions of these systems. Many of thesystems, however, lack accuracy and/or precision over the relativelywide weight range in which they are required to operate. In one set ofembodiments, the system of the invention includes a scale or set ofscales adapted to determine the amount of waste product removed fromblood, the amount of replacement fluid (infusate) in a replacement fluidreservoir, and/or both, for monitoring the progress of a treatmentand/or for accurately controlling the net amount of fluid removed fromthe patient during the treatment (or added, although this is rarelyindicated in a treatment protocol).

[0040]FIG. 4 is a schematic illustration of a blood treatment system 10in accordance with the invention. The arrangement of FIG. 4 facilitatesa method for clearing a patient's blood of toxins by providing aprotocol involving removing blood from the patient at a rate of at least300 ml/min, at least partially clearing the blood of uremic toxins tocreate cleared blood, and returning the cleared blood to the patient.The protocol can be carried out at least four times per week. A patientblood withdrawal conduit 12 is connected to the vascular system of apatient 14 at a location 16 which, in preferred embodiments, ishigh-flow rate valve port 110. Blood withdrawal conduit 12 is routedthrough a pump 18 and supplies blood to a blood treatment unit 20 via aninlet port 22. In preferred embodiments, blood treatment unit 20 is ahemofilter. Treated blood, from which waste product has been removed bysystem 20, exits treatment unit 20 at outlet 24 and is delivered, viaconduit 26, to the vascular system of patient 14 preferably by way oflocation 28 which, in preferred embodiments, is a high-flow rate port110. An ultrasonic detector 30 can be provided along line 26 betweenblood purification system 20 and patient 14 to detect any or all of flowrate, air bubbles (foam), and hematocrit. A safety clamp 32 can beprovided as well to stop flow if detector 30 indicates the presence ofunacceptable levels of air bubbles. Ultrasonic detector 30 and safetyclamp 32 can be operably and electronically linked to the treatmentcontroller, described below.

[0041] Waste product (waste filtrate in a hemofiltration system) exitsunit 20 via port 33 and passes through conduit 34 via an inlet 38 into awaste product receptacle 36. Conduit 34 passes through a pump 40. Ablood detector 35 can be positioned along conduit 34 to detect any leaksin a filter within blood treatment system 20. The detector detects redblood cells which, if a filter rupture has occurred, will leak intowaste line 34, rather than being returned to patient 14. The detectorcan be controlled by the treatment controller, and operably andelectronically linked to a system that stops treatment. An articulatedclamp 37 can be positioned along conduit 34 to control, or at least finetune, the rate of flow through pump 40. This arrangement is described ingreater detail below.

[0042] A reservoir 42 of a blood replacement fluid, or infusate, isfluidly connected to return conduit 26 via a replacement fluid conduit44 connecting an outlet 46 of reservoir 42 with a connection 48 betweenconduit 44 and conduit 26. Conduit 44 passes through a pump 50.Reservoir 42 need include only that amount of infusate required for aparticular treatment. Where a bi-daily (every other day) protocol isindicated, infusate reservoir 42 contains from about 8 to about 24liters of infusate. Where a daily protocol is indicated, reservoir 42will contain from about 8 to about 12 liters of infusate. As describedbelow, the infusate reservoir can be sold as a pre-packaged, disposablecontainer including a measured amount of infusate for one treatment. Theinvention provides a system useful for daily hemofiltration, thusreservoir 42 preferably is packaged containing from about 8 to about 12liters infusate.

[0043] A sterile filter 47 is positioned in line 44 between pump 50 andline 26.

[0044] Pumps 18, 40, and 50 are peristaltic pumps according to preferredembodiments. This is described in more detail below.

[0045] In the embodiment illustrated in FIG. 4, waste receptacle 36 andblood replacement reservoir 42 each rest upon a scale 52. In thisarrangement, a net change in patient vascular system fluid content canbe determined and thereby controlled. Since waste removed from thepatient is registered as an increase in weight on scale 52, andreplacement fluid introduced into the patient is registered as adecrease in weight on scale 52, the change in readout of scale 52 isequal to the change in net fluid level within the patient as a result ofthe treatment.

[0046] In a preferred embodiment of the invention, the pump requirementsof at least two of pumps 18, 40, and 50 are met by a single peristalticpump, and in a particularly preferred embodiment all three of pumps 18,40, and 50 are one and the same. Peristaltic pumps are known for usewith fluids other than physiological fluids, and are commerciallyavailable (for example, multi-channel pump 13-874-600, available fromFisher Scientific). This arrangement is illustrated in FIG. 5, whichshows a pump 54 (defining all of pumps 18, 40, and 50 of FIG. 4 inpreferred embodiments) including a pump race 56 and roller mechanism 58,between which each of blood withdrawal conduit 12, waste removal conduit34, and blood replacement fluid conduit 44 pass. The arrangement of FIG.5 allows for establishment of a flow of fluid through the peristalticpump and changing the rate of flow of the fluid through the pump whilethe pump operates at a constant speed and the source of fluid suppliedto the pump remains constant. That is, a constant source of fluid existsupstream of clamp 55, and the rate of flow of fluid through the pump ischanged, by closing clamp 55, while the pump operates at a constantspeed. When roller mechanism 58 rotates in a clockwise direction, asillustrated, fluid in each of conduits 12, 34, and 44 is driven in thedirection indicated by the arrows. Since the fluid flow rates inconduits 12, 34, and 44 generally will not be identical, each ofconduits 12, 34, and 44 has a cross-sectional dimension at pump 54selected to provide a different flow rate within the respective conduitat a constant pump operation speed. This is illustrated in greaterdetail in FIG. 6, which is a cross-section through lines 33 of FIG. 5.Conduits 12, 34, and 44 each are illustrated in cross-section againstinterior surface 60 of pump race 56, also shown in cross-section. Forpurposes of clarity, roller mechanism 58 is shown detached from conduits12, 34, and 44. The cross-section of conduit 12 is approximately twicethe cross-section of conduit 34, which is approximately twice thecross-section of conduit 44 in preferred embodiments, thus, rotation ofroller mechanism 58 against pump race surface 60 will cause fluid toflow in conduit 12 at a higher flow rate than within conduit 34, andfluid to flow within conduit 34 at a higher flow rate than withinconduit 44. The cross-sections of the various conduits can be adjustedfor desired flow rates. Where the tubing wall thickness differs fromconduit to conduit, a stepped pump rate can be provided.

[0047] For precise control of flow rates within lines 12, 34, and 44,that is, for precise tuning of the flow rates within these linesindependent of pump 54, auxiliary clamps can be used, for examplearticulated clamp 37 (FIG. 4). Articulated clamp 37 is illustrated alongline 34 in FIG. 5. When fluid is being driven through lines 12, 34, and44 simultaneously by pump 54, and is flowing through the lines atdifferent respective rates because of the different cross sections ofthe lines, fine tuning of the flow rate can be controlled manually, orautomatically with a feedback mechanism, with clamp 37. When clamp 37impinges upon line 34, fluid flow through the clamped conduit isrestricted causing pressure drop, thus the cross section of the conduitdownstream of the clamp will be reduced slightly due to the negativepressure. Typically, the cross section will be made slightly ovoid dueto decrease in fluid volume, thus each rotation of roller mechanism 58will cause a lesser amount of fluid to flow through that conduit whichis slightly clamped upstream of the pump. The peristaltic pump thusincludes at least a first and a second conduit each connected to asource of physiological fluid. Preferably, at least three conduitsdriven by the pump are connected to physiological fluid sources.

[0048] Referring now to FIG. 7, any disposable, single use assembly 62including a filter housing 64 integrally connected to pump race 56,along with waste receptacle 36 and infusate reservoir 42 is illustrated.The assembly is movably attachable to a blood treatment system of theinvention in a manner such that when attached, pump race 56 is engagedby roller mechanism 58 driven by the system. In assembly 62, withdrawalconduit 12 is fluidly connected to the filter housing inlet 22 andreturn conduit 26 is fluidly connected to filter housing outlet 24.Waste product conduit 34 is fluidly connected to another filter housingoutlet 33. Withdrawal conduit 12 is fluidly connectable via a connector78 to the patient's vascular system, i.e., a vein or artery (via the “T”described in application Ser. No. 08/724,948, referenced above). Returnconduit 26 is connectable via a connector 80 to the patient's vascularsystem in the same manner. The connectors 78 and 80 can be connected toa needle or fistula before or after insertion into the patient's vein orartery, optionally via port 110, described above.

[0049] Withdrawal conduit 12 and waste conduit 34 are mounted withinrace 56 such that when assembly 62 is connected to the blood treatmentcontroller, these conduits are engaged by and actuated by rollermechanism 58. In addition, replacement fluid conduit 44 is routedadjacent race surface 60 of race 56 for actuation by roller mechanism 58when the assembly is attached to the treatment system.

[0050] In the embodiment illustrated in FIG. 7, waste receptacle 36 andinfusate reservoir 42 are irremovably connected via conduits 34 and 44,respectively, to assembly 62. In this arrangement, assembly 62,including filter housing 64 and pump race 56, along with wastereceptacle 36, infusate reservoir 42, and conduits 12, 26, 34, and 44all form an integral unit that is disposable. In use, the unit isprovided with an empty waste receptacle and provided with replacementfluid in reservoir 42, with lines 44, 34, 26, and 12 optionally beingprimed. Connection of the arrangement to the patient's vascular system(described in greater detail below) via connectors 78 and 80,respectively, followed by connection of pump member (race) 56 to thetreatment controller for actuation by roller mechanism 58, andunclamping of clamps 84 and 86, respectively, renders the system readyfor use. Following a treatment protocol, the system can be detached andthe entire assembly 62, including conduits 12, 26, 34, and 44, filterhousing 64 including a filter, pump race 56, and waste receptacle 36 andinfusate reservoir 42 can be disposed of.

[0051] In the embodiment illustrated in FIG. 7, a reflective foil member84 is provided to confirm that replacement fluid flow out of reservoir82 and through conduit 44 is occurring. A light source and detector 85irradiates reflective foil member 84 for detection. A variety of sensingmechanisms such as optical sensors, ultrasonic sensors, or other sensorscan be used to detect replacement fluid flow. Preferably, wastereceptacle 34 and infusate reservoir 42 are packaged together in a box,for shipment. When the box arrives in the patient's home, the patientneed only place the box on a scale, open a lid or other opening in thebox and remove the filter, pump race, and other tubing, remove asterility barrier from each of connectors 78 and 80, and connect thesystem to the vascular system as described.

[0052] In alternative embodiments, with reference to FIG. 7, anycombination, or all, of conduits 12, 44, 34, and 26 can be mountedagainst race surface 60 of race 56. In preferred embodiments, withdrawalconduit 12, replacement fluid conduit 44, and waste conduit 34 are somounted. In one embodiment, one or both of conduits 44 and 34 aretwo-part conduits, the two-parts of each conduit joined with connectorssuch as connectors 78 and 80. In this arrangement, one or both of wastereceptacle 80 and replacement fluid reservoir 82 are reusable, anddisconnectable from disposable assembly 62 via a connector. In such anarrangement, an additional clamp is preferably provided on the assembly62 side of the connector, and the conduit is primed.

[0053] Referring now to FIG. 8, a blood treatment system 86 isillustrated including a controller housing 88 containing amicroprocessor that controls blood treatment, and that includes one ormore displays 90. A two-button device is shown, including a “start”button 94 and a “stop” button 96. An alarm light 98 indicatesmalfunction.

[0054] Housing 88 also contains a scale, the receiving surface 90 ofwhich, as illustrated, supports a container 92 containing wastereceptacle 36 and replacement fluid reservoir 42 (not shown). Assembly62 including filter housing 64, pump member (race) 56, a portion ofwithdrawal conduit 12, a portion of return conduit 70, replacement fluidconduit 44, and waste fluid conduit 34 is attached to the treatmentsystem via latches 100. When connected in this way, pump rollermechanism 58, which is mounted as an integral part of the bloodtreatment system, acts to pump fluid through conduits 12, 34, and 44.

[0055] In the arrangement illustrated, the microprocessor within housing88 controls actuation of pump roller mechanism 58 during treatment, andthe scale monitors the total weight of the waste receptacle 36 andreplacement fluid reservoir 42. The microprocessor typically will beprogrammed to allow treatment to progress so long as a gradual netweight gain of the waste receptacle and replacement fluid reservoir isobserved. This will correspond to a net fluid loss in a patient, whichis desirable. If the weight of the combination of the waste receptacleand replacement fluid reservoir strays outside of that range, alarmlight 98 will light, indicating malfunction, and the pump will stop. Thesystem can be set such that a weight change outside of a particular setof boundaries will cause the system to shut down.

[0056] One way in which the total weight of the waste receptacle andreplacement fluid reservoir can stray outside of a predetermined rangeis if there is a leak in the waste conduit. In this case, were thesystem to continue to operate, the patient would become infused withexcess replacement fluid.

[0057] Referring now to FIG. 9, a blood treatment system 210 accordingto another aspect of the invention is illustrated. In system 210, afirst scale 212 is provided along with a second scale 214. Scale 212, asillustrated, rests on a scale surface 216 of scale 114, thus scale 114registers the weight of waste receptacle 36 and replacement fluidreservoir 42, and scale 112 registers only the weight of replacementfluid reservoir 42. In this manner, as replacement fluid is consumed andwaste receptacle 36 is filled, scale 114 will display a net change thatequals the difference between replacement fluid consumed and wasteproduct recovered. Scale 112 will display only a change in weightresulting from consumption of replacement fluid. This arrangement ismore sensitive than prior art systems involving one scale fordetermination of weight of waste product and another scale fordetermination of weight of replacement fluid for the following reasons.In the embodiment illustrated, if 10,000 grams of replacement fluidexists initially in reservoir 42, and all is consumed during theprocedure, and the waste receptacle 36 is empty at the beginning of theprocedure and contains 11,000 grams waste at the end of the procedure,then scale 112 will record 10,000 grams initially, and zero gramsfinally, and scale 114 will record 10,000 grams initially and 11,000grams finally. A scale that is required to operate over a smaller rangeof weight typically will provide more accurate and precise weightinformation. Since accurate weight information is important in the bloodtreatment protocol, it is preferred that the weight range through whichscale 114 must record data be minimized. The arrangement of FIG. 9provides this minimization of required range of scale readout. In oneaspect of the arrangement of FIG. 9 that is particularly preferred,scale 114, which records 300 grams initially and 500 grams finally,operates over a range of only 200 grams. This allows greater precisionin scale 14, and precision is particularly important in measuring thenet change in fluid content of the patient during treatment. One scale(212) is used only to determine that the infusate is being pumped. Ahigh level of accuracy is not required in this determination.

[0058] Referring again to FIG. 4, in combination with FIGS. 5-9, aseries of embodiments of the invention that provide for a range indegree of disposability, and that provides for simple operation of thesystem of the invention in the home, are described. Referring to FIGS. 4and 7, a system which is essentially completely disposable with theexception of the system controller and scales (described above),involves a disposable filter and filter housing 20, disposable pump race56, disposable waste receptacle 36 and infusate reservoir 42, anddisposable conduits 12, 34, 44, and 26. The system can be entirelypre-primed, with the only required assembly by the user, in the home,involving removal of the described system from a package, and attachmentof the system, fluidly, at only two locations (connectors 78 and 80) toa conduit that establishes fluid communication with the vascular systemof the patient via needles to port 110. In one set of embodiments,connectors 78 and 80 insert directly into high flow rate access port110. In another set of embodiments, each of connectors 78 and 80 isfluidly connectable to a fistula set including a needle or other devicefor insertion into port 110 or to percutaneous catheters. Other thanconnection of the assembly to the vascular system of the patient viaconnectors 78 and 80, the filter housing 64/pump race 56 assembly needonly be fastened to controller 88 via latches 100, and the controllercan be started simply by pushing button 94.

[0059] In another arrangement, the filter is reusable (can beregenerated by the user) and can be cleaned between uses, but lines 12,34, 44, and 26, and the waste receptacle and infusate reservoir aredisposable after one use. In this embodiment, the simple two-connectorassembly, along with attachment of the filter/pump race assembly to thecontrol unit, requires only the additional insertion of the regeneratedfilter into the filter housing. The filter housing can have an openingat one end thereof which is removable, allowing the filter to be removedand inserted easily without requirement of any other conduitdisconnections or connections. Alternatively, the system can be designedso that the filter can be regenerated while remaining in the filterhousing by attachment of regeneration lines to the filter housing andappropriate treatment. Where the filter and filter housing both areremovable, conduits 12 and 26 can be removed from the filter housing anddisposed, and during the next use new conduits attached.

[0060] In another aspect of the invention, a system for removal ofuremic toxins from blood is equipped to accurately measure arterialblood pressure without, at any location in the system, a drip chamber.Drip chambers are used to measure blood pressure, but can bedisadvantageous since at high flow rates they can infuse bubbles intothe flow of blood, which is problematic. Additionally, drip chambers addcost. In the present invention (with reference to FIG. 4), ultrasonicblood flow detector 30 can be used to measure arterial blood pressure asfollows. The speed of rotation of peristaltic pump 18 will give anindication of blood flow rate, but this indication may be inaccurate (asis known for peristaltic pumps) due to negative pressure. The flow rateprovided by ultrasonic sensor 30 is very accurate, however, andcomparison of the actual flow rate from sensor 30 with the indicatedflow rate of pump 18, and comparison of the difference between thesevalues, can provide one of ordinary skill in the art with actualpressure in withdrawal conduit 12 which typically is fluidly connectedto a patient's artery.

What is claimed is:
 1. A method of clearing a patient's blood of uremic toxins, comprising: subjecting a patient in need of renal therapy to a protocol involving continuously removing blood from a patient at a blood flow rate of at least 300 ml/min, at least partially clearing the blood of uremic toxins to create cleared blood, and continuously returning the cleared blood to the patient; and repeating the protocol at least 4 times in one week.
 2. A method as in claim 1 , comprising subjecting the patient to a protocol involving renal therapy at a blood flow rate of at least 400 ml/min, and repeating the protocol at least 4 times in one week.
 3. A method as in claim 1 , comprising subjecting the patient to a protocol involving renal therapy at a blood flow rate of at least 500 ml/min, and repeating the protocol at least 4 times in one week.
 4. A method as in claim 1 , comprising subjecting the patient to a protocol involving renal therapy at a blood flow rate of at least 600 ml/min, and repeating the protocol at least 4 times in one week.
 5. A method as in claim 1 , comprising accessing a patient's vascular system through a subcutaneous port, removing the blood from the patient, at least partially clearing the blood of uremic toxins to create cleared blood, and returning the cleared blood to the patient subcutaneously.
 6. A method as in claim 1 , the protocol involving allowing uremic toxins in the patient's blood to reach no more than about 80% of the maximum level compared to thrice-weekly therapy levels, and treating the patient's blood to reduce uremic toxins in the blood to a level no less than about 20% minimum level.
 7. A method as in claim 1 , the protocol involving subjecting the patient to hemofiltration.
 8. A method as in claim 7 , comprising subjecting the patient to hemofiltration using a hemofiltration system including a disposable infusate reservoir containing from about 4 to about 18 liters infusate.
 9. A method as in claim 1 , comprising subjecting the patient to a protocol using a system including: a filter having a first side and a second side; an input conduit in fluid communication with the first side of the filter and fluidly connectable to a patient's blood stream; a return conduit in fluid communication with the first side of the filter for returning cleared blood to the patient's blood stream; a waste receptacle; a waste conduit fluidly connecting the waste receptacle to the second side of the filter; a reservoir containing from about 4 to about 25 liters of infusate; an infusate conduit fluidly connecting the reservoir to the return conduit.
 10. A method as in claim 9 , wherein the reservoir, contains from about 4 to about 18 liters infusate.
 11. A method as in claim 9 , wherein the filter, input conduit, return conduit, waste receptacle, waste conduit, and infusate reservoir together comprise a self-contained, disposable unit packaged together and operable in combination with a pump and a controller by making no more than two fluid connections within the unit including fluidly connecting the input conduit and the return conduit to a patient's blood stream.
 12. A method as in claim 1 , the protocol involving clearing a patient's blood of uremic toxins via hemofiltration at an effective clearance rate of at least 100 ml/min.
 13. A method comprising clearing a patient's blood of uremic toxins via hemofiltration at an effective clearance rate of at least 100 ml/min
 14. A method as in claim 13 , comprising: subjecting a patient in need of renal therapy to a protocol involving allowing uremic toxins in the patient's blood to reach no more than about 80% of the maximum level compared to those levels encountered in thrice-weekly therapy, treating the patient's blood to reduce uremic toxins in the blood to a level no less than about 20% of the maximum level compared to those levels encountered in thrice-weekly therapy; and repeating the protocol at least four times in one week.
 15. A method as in claim 13 , comprising clearing the patient's blood of uremic toxins via a system including: a filter having a first side in fluid communication with a source of a patient's blood and a second side in fluid communication with a waste receptacle; and a reservoir containing from about 4 to about 25 liters of infusate fluidly connectable to the patient's blood stream.
 16. A method as in claim 15 , wherein the reservoir contains from about 4 to about 18 liters infusate.
 17. A method as in claim 13 , comprising clearing the patient's blood of uremic toxins via a system including: a filter having a first side and a second side; an input conduit in fluid communication with the first side of the filter and fluidly connectable to a patient's blood stream; a return conduit in fluid communication with the first side of the filter for returning cleared blood to the patient's blood stream; a waste receptacle; a waste conduit fluidly connecting the waste receptacle to the second side of the filter; a reservoir containing from about 4 to about 25 liters of infusate; an infusate conduit fluidly connecting the reservoir to the return conduit.
 18. A method as in claim 17 , wherein the reservoir contains from about 4 to about 18 liters infusate.
 19. A method as in claim 17 , wherein the filter, input conduit, return conduit, waste receptacle, waste conduit, reservoir, and infusate conduit together comprise a self-contained, disposable unit packaged together and operable in combination with a pump and a controller by making no more than two fluid connections within the unit including fluidly connecting the input conduit and the return conduit to a patient's blood stream.
 20. A method comprising: subjecting a patient in need of renal therapy to a protocol involving allowing uremic toxins in the patient's blood to reach no more than about 80% of the maximum level compared to thrice-weekly therapy levels, treating the patient's blood to reduce uremic toxins in the blood to a level no less than about 20% of the maximum level compared to thrice-weekly therapy levels; and repeating the protocol at least 4 times in one week.
 21. A method as in claim 20 , comprising subjecting the patient to the protocol using a self-contained system including a filter having a first side in fluid communication with a source of a patient's blood and a second side in fluid communication with a waste receptacle; and a reservoir containing from about 4 to about 25 liters of infusate fluidly connectable to the patient's blood stream.
 22. A method as in claim 21 , wherein the reservoir contains from about 4 to about 18 liters infusate.
 23. A method as in claim 20 , comprising subjecting a patient to the protocol using a system including: a filter having a first side and a second side; an input conduit in fluid communication with the first side of the filter and fluidly connectable to a patient's blood stream; a return conduit in fluid communication with the first side of the filter for returning cleared blood to the patient's blood stream; a waste receptacle; a waste conduit fluidly connecting the waste receptacle to the second side of the filter; a reservoir containing from about 4 to about 25 liters of infusate; an infusate conduit fluidly connecting the reservoir to the return conduit.
 24. A method as in claim 23 , wherein the reservoir contains from about 4 to about 18 liters infusate.
 25. A method as in claim 23 , wherein the filter, input conduit, return conduit, waste receptacle, waste conduit, reservoir, and infusate conduit together comprise a self-contained, disposable unit packaged together and operable in combination with a pump and a controller by making no more than two fluid connections within the unit including fluidly connecting the input conduit and the return conduit to a patient's blood stream.
 26. A self-contained system for clearing a patient's blood of uremic toxins, comprising: a filter having a first side fluidly connectable to a source of a patient's blood and a second side fluidly connectable to a waste receptacle; and a reservoir containing from about 4 to about 25 liters of infusate fluidly connectable to the patient's blood stream.
 27. A system as in claim 26 , wherein the reservoir contains from about 4 to about 18 liters infusate.
 28. A system as in claim 26 , comprising: a filter having a first side and a second side; an input conduit in fluid communication with the first side of the filter and fluidly connectable to a patient's blood stream; a return conduit in fluid communication with the first side of the filter for returning cleared blood to the patient's blood stream; a waste receptacle; a waste conduit fluidly connecting the waste receptacle to the second side of the filter; a reservoir containing from about 4 to about 25 liters of infusate; an infusate conduit fluidly connecting the reservoir to the return conduit.
 29. A system as in claim 28 , the reservoir containing from about 4 to about 18 liters infusate.
 30. A system as in claim 28 , wherein the filter, input conduit, return conduit, waste receptacle, waste conduit, reservoir, and infusate conduit reservoir together comprise a self-contained, disposable unit packaged together and operable in combination with a pump and a controller by making no more than two fluid connections within the unit including fluidly connecting the input conduit and the return conduit to a patient's blood stream.
 31. A system for clearing a patient's blood of uremic toxins, comprising: a filter having a first side and a second side; an input conduit in fluid communication with the first side of the filter and fluidly connectable to a patient's blood stream; a return conduit in fluid communication with the first side of the filter for returning cleared blood to the patient's blood stream; a waste receptacle; a waste conduit fluidly connecting the waste receptacle to the second side of the filter; a reservoir containing from about 4 to about 25 liters of infusate; and an infusate conduit fluidly connecting the reservoir to the return conduit.
 32. A system as in claim 31 , the reservoir containing from about 4 to about 18 liters infusate.
 33. A system as in claim 31 , wherein the filter, the input conduit, the return conduit, waste receptacle, the waste conduit, the infusate reservoir, and the reservoir together comprise a self-contained, disposable unit packaged together and operable in combination with a pump and a controller by making no more than two fluid connections within the unit including fluidly connecting the input conduit and the return conduit to a patient's blood stream.
 34. A system as in claim 33 , wherein the self-contained unit further comprises a pump member surface that mates with a pump in a treatment controller when the unit is attached to the treatment controller and at least two conduits of the input conduit, the waste conduit, the infusate conduit, and the return conduit are arranged proximate the pump member surface such that when the unit is attached to the treatment controller the at least two conduits are actuable by the pump.
 35. A system comprising: a peristaltic pump; a fluid conduit passing through the pump and having a portion upstream of the pump; and a valve in the portion of the fluid conduit upstream of the pump.
 36. A system as in claim 35 , wherein the valve is movable between a first position creating a first degree of resistance to fluid flow past the valve and a second position creating a second degree of resistance to fluid flow past the valve greater than the first degree of resistance.
 37. A system as in claim 36 , wherein the valve is operably linked to a controller responsive to a flow sensor.
 38. A system as in claim 35 , the fluid conduit constructed and arranged to receive a physiological fluid.
 39. A system as in claim 34 , the fluid conduit containing a physiological fluid.
 40. A method comprising: adjusting the rate of fluid flow through a peristaltic pump by adjusting the resistance to fluid flow upstream of the pump.
 41. A method as in claim 40 , the adjusting step involving moving a valve, of a fluid conduit supplying fluid to the peristaltic pump, towards a closed position.
 42. A method as in claim 40 , comprising adjusting the rate of flow of a physiological fluid through the peristaltic pump.
 43. A method comprising: establishing a flow of fluid through a peristaltic pump from a source of the fluid; and changing the rate of flow of the fluid through the peristaltic pump while the pump operates at a constant speed and the source of fluid remains constant.
 44. A method as in claim 43 , involving establishing a flow of physiological fluid through the peristaltic pump and changing the rate of flow of the physiological fluid.
 45. A method as in claim 43 , the changing step involving adjusting the resistance to fluid flow upstream of the pump.
 46. A method as in claim 45 , involving adjusting the resistance to fluid flow by moving a valve of a fluid conduit supplying the pump towards a closed position.
 47. A method comprising: controlling an amount of a replacement fluid added from a reservoir to a blood stream of a patient in response to a signal generated from comparison of (a) a total amount of an accumulated waste product removed from the blood stream and the replacement fluid in the reservoir with (b) one of the amount of the accumulated waste product and the replacement fluid in the reservoir.
 48. A method as in claim 47 , comprising: accumulating a waste product removed from a blood stream of a patient; adding a replacement fluid to the blood stream from a reservoir of replacement fluid; monitoring a total amount of the accumulated waste product plus the replacement fluid in the reservoir; monitoring an amount of at least one of the accumulated waste product and the replacement fluid in the reservoir; comparing the total amount of the accumulated waste product and the replacement fluid in the reservoir with the at least one of the accumulated waste product and the replacement fluid in the reservoir to generate a signal; and controlling an amount of replacement fluid added to the blood stream in response to the signal.
 49. A system comprising: a blood treatment device having an input fluidly connectable to a source of blood drawn from a patient in need of renal treatment and an output fluidly connectable to a receptacle of blood waste product; a first scale adapted to determine a first value that is a total amount of the content of the receptacle of blood waste product plus an amount of blood replacement fluid in a reservoir; a second scale adapted to determine a second value that is at least one of the content of the receptacle of blood waste product and the amount of blood replacement fluid in the reservoir; a microprocessor capable of generating a signal indicative of a comparison of the first value and the second value; and a controller capable of controlling delivery of blood replacement fluid to the patient's blood stream in response to the signal.
 50. A system as in claim 49 , wherein the fluid treatment device is a filter housing.
 51. A system as in claim 49 , wherein the fluid treatment device is a filter.
 52. A system as in claim 49 , wherein the fluid treatment device is removably securable to a housing of the microprocessor.
 53. A system as in claim 49 , further comprising a first fluid pump having an inlet fluidly connectable to the source of blood and an outlet fluidly connectable to the blood treatment device.
 54. A system as in claim 53 , wherein the fluid treatment device is removably securable to the fluid pump.
 55. A system as in claim 53 , wherein the fluid treatment device is attached to the fluid pump.
 56. A system as in claim 55 , wherein the fluid treatment device is removably securable to a housing of the microprocessor.
 57. A system as in claim 49 , further comprising a second fluid pump having an inlet fluidly connectable to the blood treatment device and an outlet fluidly connectable to the waste product receptacle.
 58. A system as in claim 57 , wherein the first and second fluid pumps are driven by a single driving mechanism.
 59. A system as in claim 58 , wherein each of the first and second fluid pumps comprises a fluid pathway addressed by a common peristaltic pump apparatus.
 60. A system as in claim 57 , further comprising a third fluid pump having an inlet fluidly connectable to the reservoir of blood replacement fluid and an outlet fluidly connectable to the patient's blood stream.
 61. A system as in claim 60 , wherein each of the first and third fluid pumps comprises a fluid pathway addressed by a common peristaltic pump apparatus.
 62. A system as in claim 60 , wherein each of the second and third fluid pumps comprises a fluid pathway addressed by a common peristaltic pump apparatus.
 63. A system as in claim 60 , wherein each of the first, second, and third fluid pumps comprises a fluid pathway addressed by a common peristaltic pump apparatus.
 64. A system comprising: a peristaltic pump including a fluid conduit and a rotatable actuator that urges fluid flow within the conduits upon rotation, the first conduit connected to a source of physiological fluid.
 65. A system as in claim 64 , wherein the peristaltic pump is a multi-conduit peristaltic pump including a second fluid conduit, wherein the rotatable actuator urges fluid flow within the conduit and the second conduit upon rotation, both conduits being connected to a physiological fluid source.
 66. A method comprising: urging simultaneously the flow of first and second physiological fluids within first and second conduits, respectively, via actuation of a single fluid pump actuator.
 67. A method as in claim 66 comprising urging the flow of the first and second physiological fluids via actuation of a peristaltic pump.
 68. A fluid pump constructed and arranged for use with a blood treatment system, the treatment system including a blood treatment device, a withdrawal conduit arranged to supply a source of blood from a patient in need of renal treatment to the treatment device, a return conduit arranged to return treated blood from the treatment device to the patient, a waste product conduit arranged to deliver waste product removed from the blood by the treatment device to a waste outlet, and a replacement fluid conduit arranged to deliver a replacement fluid to the patient, wherein the fluid pump is constructed and arranged to urge fluid to flow within at least two of the withdrawal conduit, the return conduit, the waste product conduit, and the replacement fluid conduit.
 69. A fluid pump as in claim 68 , constructed and arranged to urge fluid to flow within at least three of the withdrawal conduit, the return conduit, the waste product conduit, and the replacement fluid conduit.
 70. A fluid pump as in claim 68 , constructed and arranged to urge fluid to flow within each of the withdrawal conduit, the waste product conduit, and the replacement fluid conduit.
 71. A fluid pump as in claim 68 comprising a race and a peristaltic roller member, constructed to receive between the race and roller member the at least two conduits.
 72. An assembly for use with a blood treatment system that is removably attachable to the system, comprising: a blood filter housing having an inlet and a first outlet and a second outlet; a pump member having a surface that mates with a pump in the treatment system when the assembly is attached to the treatment system; a withdrawal conduit in fluid communication with the filter housing inlet and fluidly connectable to a source of blood from a patient in need of renal treatment; a return conduit in fluid communication with the first filter housing outlet and fluidly connectable to a conduit for returning treated blood to the patient; and a waste product conduit in fluid communication with the second filter housing outlet, at least two of the withdrawal conduit, the return conduit, and the waste product conduit being arranged proximate the pump member surface such that, when the assembly is attached to the treatment system, the at least two conduits are actuable by the pump.
 73. An assembly as in claim 72 , constructed and arranged such that when the assembly is attached to the treatment system, at least two of the withdrawal conduit, the return conduit, the waste product conduit, and a replacement fluid conduit arranged to deliver a replacement fluid to the patient are actuable by the pump.
 74. An assembly as in claim 73 , wherein at least two of the withdrawal conduit, the return conduit, the waste product conduit, and the replacement fluid conduit pass between a the pump member surface and a pump roller assembly of the pump when the assembly is attached to the treatment system.
 75. An assembly as in claim 72 , wherein the assembly is provided in combination with instructions for a single use followed by disposal.
 76. An assembly as in claim 72 , wherein the assembly is readily attachable and detachable by a patient from a housing containing a microprocessor for controlling actuation of the pump.
 77. An assembly as in claim 76 , wherein the a waste product conduit is fluidly connectable to a waste product container and the replacement fluid conduit is fluidly connectable to a replacement fluid reservoir.
 78. A blood treatment system assembly as in claim 77 , wherein the a waste product conduit is fluidly connectable to a waste product container and the replacement fluid conduit is fluidly connectable to a replacement fluid reservoir that forms an integral unit with the waste product container.
 79. A blood treatment system assembly as in claim 77 , wherein the a waste product conduit is fluidly connectable to a waste product container and the replacement fluid conduit is fluidly connectable to a replacement fluid reservoir that forms a single, disposable unit with the waste product container.
 80. A system comprising: a conduit fluidly connectable to a patient's vascular system; and an ultrasonic sensor responsive to fluid flow in the conduit and including an output for delivering a signal indicative of fluid flow rate in the conduit.
 81. A system as in claim 80 , further comprising an alarm responsive to the signal delivered by the ultrasonic sensor, arranged to be activated when the fluid flow rate.
 82. A system as in claim 81 , wherein the alarm is activated when the fluid flow rate drops below a predetermined rate.
 83. A system for clearing a patient's blood of uremic toxins, comprising: a subcutaneous port providing fluid communication with a patient's vascular system; a filter having a first side and a second side; an input conduit in fluid communication with the first side of the filter and fluidly connectable to the subcutaneous port; a return conduit in fluid communication with the first side of the filter for returning cleared blood to the patient's blood stream; a waste receptacle; a waste conduit fluidly connecting the waste receptacle to the second side of the filter; a reservoir containing from about 4 to about 25 liters of infusate; and an infusate conduit fluidly connecting the reservoir to the return conduit, wherein the system is constructed and arranged to continuously clear the blood of uremic toxins to create cleared blood at a blood flow rate of at least 300 ml/min.
 84. A method as in claim 1 , comprising repeating the protocol at least five times in one week.
 85. A method as in claim 1 , comprising repeating the protocol at least six times in one week.
 86. A method as in claim 2 , comprising repeating the protocol at least five times in one week.
 87. A method as in claim 2 , comprising repeating the protocol at least six times in one week.
 88. A method as in claim 3 , comprising repeating the protocol at least five times in one week.
 89. A method as in claim 3 , comprising repeating the protocol at least six times in one week.
 90. A method as in claim 4 , comprising repeating the protocol at least five times in one week.
 91. A method as in claim 4 , comprising repeating the protocol at least six times in one week.
 92. A method as in claim 8 , wherein the disposable infusate reservoir contains from about 9 to about 13 liters infusate.
 93. A method as in claim 8 , wherein the disposable infusate reservoir contains from about 10 to about 12 liters infusate.
 94. A method as in claim 9 , wherein the reservoir contains from about 9 to about 13 liters infusate.
 95. A method as in claim 15 , wherein the reservoir contains from about 9 to about 13 liters infusate.
 96. A method as in claim 17 , wherein the reservoir contains from about 9 to about 13 liters infusate.
 97. A method as in claim 23 , wherein the reservoir contains from about 9 to about 13 liters infusate.
 98. A method as in claim 26 , wherein the reservoir contains from about 9 to about 13 liters infusate.
 99. A method as in claim 28 , wherein the reservoir contains from about 9 to about 13 liters infusate.
 100. A method as in claim 31 , wherein the reservoir contains from about 9 to about 13 liters infusate. 